Pathogenesis of SLE

Part 1: Characterization of the phenotype and function of (autoreactive) B cell and plasma cell subsets

Several different B cell subsets have been described to be involved in SLE, including activated naive B cells, age/autoimmunity-associated B cells, marginal zone B cells, and switched memory B cells. These B cell subsets arise through various activation and differentiation pathways, and may give rise to plasma cells to secrete antibodies. Plasma cell differentitation can be influenced by other factors, such as cytokines, interactions with other immune cells. Since it is not known which activation pathways are involved in production of pathogenic autoantibodies in SLE, several of our projects deal with the identification and characterization of autoreactive B cells and plasma cells, with emphasis on the major nuclear antigens that are recognized by anti-nuclear antibodies (ANA).

In addition, despite our increased understanding of B cell subsets and phenotypes, very little is known about plasma cell phenotypes. Since plasma cells constitute an interesting cellular target for new treatment strategies, we have developed assays to identify and characterize (antigen-specific) plasma cells by spectral flow cytometry, scRNAseq, and B cell receptor (BCR) repertoire analysis. We identified several novel plasma cell phenotypes that we are currently characterizing functionally, with the aim to link B cell precursor subsets to their activation pathways, and to the resulting plasma cell subsets they give rise to.  

Part 2: Characterization of autoantibodies

In these projects, we aim to characterize in detail the autoantibodies in SLE. Anti-nuclear antibodies (ANA) consist of a plethora of different reactivities that can each have unique properties. Furthermore, there is heterogeneity between patients. We characterize ANA antibodies with respect to their specificity, isotype, glycosylation, and more. Furthermore, we relate autoantibody profiles to different B cell phenotypes to find causal B cell activation pathways responsible for each type of autoantibody. Additionally, we analyse the effects of B cell-targeted therapies on autoantibody characteristics.

Part 3: Development of patient stratification

Disease heterogeneity is often considered the most important barrier to achieve more effective treatment in SLE, with only 1 new drug being approved in the last ~60 years. Postdoctoral studies by Dr. Suurmond in the Diamond lab (Feinstein Institutes for Medical research, NY, USA), revealed distinct SLE patient groups with different autoreactive B cell phenotypes. These B cell phenotypes may relate to the pathway for autoantibody production that is most active in each individual patient, and therefore may constitute a biomarker for prediction of therapeutic effectiveness. In this project, we now aim to develop a personalized medicine approach by testing if this B cell phenotyping can be used to stratify patients and predict their response to B cell-targeted therapies. For these studies we work together with the group of dr. Onno Teng (dept. of Nephrology, LUMC), prof. Betty Diamond (Feinstein Institutes for Medical Research, NY, USA) and the Immune Tolerance Network (USA).